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An experimental and modeling study investigating the ignition delay in a military diesel engine running hexadecane (cetane) fuel

Journal Article · · International Journal of Engine Research
 [1];  [1];  [1];  [1];  [2];  [2]
  1. U.S. Naval Academy, Annapolis, MD (United States)
  2. Lawrence Livermore National Lab. (LLNL), Livermore, CA (United States)
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In an effort aimed at predicting the combustion behavior of a new fuel in a conventional diesel engine, cetane (n-hexadecane) fuel was used in a military engine across the entire speed–load operating range. The ignition delay was characterized for this fuel at each operating condition. A chemical ignition delay was also predicted across the speed–load range using a detailed chemical kinetic mechanism with a constant pressure reactor model. At each operating condition, the measured in-cylinder pressure and predicted temperature at the start of injection were applied to the detailed n-hexadecane kinetic mechanism, and the chemical ignition delay was predicted without any kinetic mechanism calibration. The modeling results show that fuel–air parcels developed from the diesel spray with an equivalence ratio of 4 are the first to ignite. The chemical ignition delay results also showed decreasing igntion delays with increasing engine load and speed, just as the experimental data revealed. At lower engine speeds and loads, the kinetic modeling results show the characteristic two-stage negative temperature coefficient behavior of hydrocarbon fuels. However, at high engine speeds and loads, the reactions do not display negative temperature coefficient behavior, as the reactions proceed directly into high-temperature pathways due to higher temperatures and pressure at injection. A moderate difference between the total and chemical ignition delays was then characterized as a phyical delay period that scales inversely with engine speed. This physical delay time is representative of the diesel spray development time and is seen to become a minority fraction of the total igntion delay at higher engine speeds. In addition, the approach used in this study suggests that the ignition delay and thus start of combustion may be predicted with reasonable accuracy using kinetic modeling to determine the chemical igntion delay. Then, in conjunction with the physical delay time (experimental or modeling based), a new fuel’s acceptability in a conventional engine could be assessed by determining that the total ignition delay is not too short or too long.

Research Organization:
Lawrence Livermore National Lab., Livermore, CA (United States)
Sponsoring Organization:
USDOE
Grant/Contract Number:
AC52-07NA27344
OSTI ID:
1281692
Report Number(s):
LLNL-JRNL--590393
Journal Information:
International Journal of Engine Research, Journal Name: International Journal of Engine Research Journal Issue: 1 Vol. 14; ISSN 1468-0874
Publisher:
SAGECopyright Statement
Country of Publication:
United States
Language:
English

References (7)

Camelina-derived jet fuel and diesel: Sustainable advanced biofuels journal June 2010
A comprehensive detailed chemical kinetic reaction mechanism for combustion of n-alkane hydrocarbons from n-octane to n-hexadecane journal January 2009
Comprehensive chemical kinetic modeling of the oxidation of 2-methylalkanes from C7 to C20 journal December 2011
Kinetic modeling of gasoline surrogate components and mixtures under engine conditions journal January 2011
Chemical Kinetic Modeling Study of the Effects of Oxygenated Hydrocarbons on Soot Emissions from Diesel Engines journal June 2006
Estimating Heat-Release and Mass-of-Mixture Burned from Spark-Ignition Engine Pressure Data journal August 1987
Understanding Ignition Delay Effects With Pure Component Fuels in a Single-Cylinder Diesel Engine journal November 2010

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Related Subjects

30 DIRECT ENERGY CONVERSION
cetane
combustion kinetics
diesel
engine
fuel
hexadecane
ignition delay